Electrochemical Technologies for Energy Storage and Conversion, 2 Volumes

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In this handbook and ready reference, editors and authors from academia and industry share their in-depth knowledge of known and novel materials, devices and technologies with the reader. The result is a comprehensive overview of electrochemical energy and conversion methods, including batteries, fuel cells, supercapacitors, hydrogen generation and storage as well as solar energy conversion. Each chapter addresses electrochemical processes, materials, components, degradation mechanisms, device assembly and manufacturing, while also discussing the challenges and perspectives for each energy storage device in question. In addition, two introductory chapters acquaint readers with the fundamentals of energy storage and conversion, and with the general engineering aspects of electrochemical devices.With its uniformly structured, self-contained chapters, this is ideal reading for entrants to the field as well as experienced researchers.

Inhaltsverzeichnis

Volume 1ELECTROCHEMICAL TECHNOLOGIES FOR ENERGY STORAGE AND CONVERSIONIntroductionGlobal Energy Status: Demands, Challenges, and Future PerspectivesDriving Forces behind Clean and Sustainable Energy SourcesGreen and Sustainable Energy Sources and Their Conversion: Hydro, Biomass, Wind, Solar, Geothermal, and BiofuelElectrochemistry: a Technological OverviewElectrochemical Rechargeable Batteries and Supercapacitors (Li Ion Batteries, Lead-Acid Batteries, NiMH Batteries, Zinc-Air Batteries, Liquid Redox Batteries)Light Fuel Generation and Storage: Water Electrolysis, Chloro-Alkaline Electrolysis, Photoelectrochemical and Photocatalytic H2 Generation, and Electroreduction of CO2Fuel Cells: Fundamentals to Systems (Phosphoric Acid Fuel Cells, PEM Fuel Cells, Direct Methanol Fuel Cells, Molten Carbon Fuel Cells, and Solid Oxide Fuel Cells)SummaryELECTROCHEMICAL ENGINEERING FUNDAMENTALSElectrical Current/Voltage, Faraday?s Laws, Electric Efficiency, and Mass BalanceElectrode Potentials and Electrode-Electrolyte InterfacesElectrode Kinetics (Charger Transfer (Butler-Volmer Equation) and Mass Transfer (Diffusion Laws))Porous Electrode Theory (Kinetic and Diffusion)Structure, Design, and Fabrication of Electrochemical DevicesNanomaterials in Electrochemical ApplicationsLITHIUM ION RECHARGEABLE BATTERIESIntroductionMain Types and Structures of Li Ion Rechargeable BatteriesElectrochemical Processes in Li Ion Rechargeable BatteriesBattery Components (Anode, Cathode, Separator, Endplates, and Current Collector)Assembly, Stacking, and Manufacturing of Li Ion Rechargeable BatteriesLi Ion Battery Performance, Testing, and DiagnosisDegradation Mechanisms and Mitigation StrategiesCurrent and Potential Applications of Secondary Li Ion BatteriesLEAD-ACID BATTERYGeneral Characteristics and Chemical/Electrochemical Processes in a Lead-Acid BatteryBattery Components (Anode, Cathode, Separator, Endplates (Current Collector), and Sealing)Main Types and Structures of Lead-Acid BatteriesCharging Lead-Acid BatteryMaintenance and Failure Mode of a Lead-Acid BatteryAdvanced Lead-Acid Battery TechnologyLead-Acid Battery MarketNICKEL-METAL HYDRIDE (Ni-MH) RECHARGEABLE BATTERIESIntroduction to NiMH Rechargeable BatteriesElectrochemical Processes in Rechargeable Ni-MH BatteriesBattery ComponentsAssembly, Stacking, Configuration, and Manufacturing of Rechargeable Ni-MH BatteriesNi-MH Battery Performance, Testing, and DiagnosisDegradation Mechanisms and Mitigation StrategiesApplications (Portable, Backup Power, and Transportation)Challenges and Perspectives of Ni-MH Rechargeable BatteriesMETAL-AIR TECHNOLOGYMetal-Air TechnologyIntroduction to Aluminum-Air TechnologyIntroduction to Lithium-Air TechnologyIntroduction to Zinc-Air TechnologyIntroduction to Magnesium-Air TechnologyStructure of Magnesium-Air CellComponentsManufacturingMagnesium-Air Battery PerformanceDegradation Mechanisms and Mitigation StrategiesApplicationsChallenges and Perspectives of Magnesium-Air CellsLIQUID REDOX RECHARGEABLE BATTERIESIntroductionElectrochemical Processes in a Redox Flow BatteryMaterials and Properties of Redox Flow BatteryRedox Flow Battery SystemPerformance Evaluation of Redox Flow BatteryDegradation Mechanisms and Mitigation StrategiesApplications of Redox Flow BatteriesPerspectives and Challenges of RFBELECTROCHEMICAL SUPERCAPACITORSIntroduction to Supercapacitors (Current Technology State and Literature Review)Main Types and Structures of SupercapacitorsPhysical/Electrochemical Processes in SupercapacitorsSupercapacitor ComponentsAssembly and Manufacturing of SupercapacitorsSupercapacitors Stacking and SystemsSupercapacitor Performance, Testing, and DiagnosisSupercapacitor ConfigurationsApplicationsChallenges and Perspectives of Electrochemical SupercapacitorsVolume 2WATER ELECTROLYSIS FOR HYDROGEN GENERATIONIntroduction to Water ElectrolysisThermodynamicsKineticsAlkaline Water ElectrolysisPEM Water ElectrolysisHigh Temperature Water ElectrolysisConclusionHYDROGEN COMPRESSION, PURIFICATION, AND STORAGEIntroductionPressurized Water ElectrolysisHydrogen Electrochemical CompressionHydrogen Electrochemical Extraction and PurificationHydrogen Storage in Hydride-Forming MaterialsConclusion and PerspectivesSOLAR CELL AS AN ENERGY HARVESTING DEVICEIntroductionSolar Radiation and AbsorptionFundamentals of Solar CellsSilicon Solar CellOther High-Efficiency Solar CellsDye-Sensitized Solar CellRoutes to Boost the Efficiency of Solar CellsCurrent Ideas for Future Solar CellSummaryPHOTOELECTROCHEMICAL CELLS FOR HYDROGEN GENERATIONIntroductionMain Types and Structures of Photoelectrochemical CellsElectrochemical Processes in Photoelectrochemical CellsPhotoelectrochemical Cell ComponentsAssembly of Photoelectrochemical CellsPhotoelectrochemical Cell Performance, Testing, and DiagnosisDegradation Mechanisms and Mitigation StrategiesApplications (Portable, Stationary, and Transportation)ConclusionsPOLYMER ELECTROLYTE MEMBRANE FUEL cellsIntroduction to PEMFCsMain Types and Structures of PEMFCsElectrochemical Processes in PEMFCsPEMFCs ComponentsAssembly and Manufacture of PEMFCsPEMFC Stacking and SystemPEM Performance, Testing, and DiagnosisDegradation Mechanisms and Mitigation StrategiesApplicationsChallenges and PerspectivesSOLID OXIDE FUEL CELLSIntroductionFuel Cell ComponentsAssembly and ManufacturingStacking and Balance of the PlantPerformance, Testing, and DiagnosisDegradation Mechanisms and Mitigation StrategiesApplicationsChallenges and PerspectivesDIRECT METHANOL FUEL CELLSIntroduction to Direct Methanol Fuel CellsMain Types and Structures of Direct Methanol Fuel CellsElectrochemical Processes in Direct Methanol Fuel CellsFuel Cell ComponentsAssembly and Manufacturing of Direct Methanol Fuel CellsDirect Methanol Fuel Cell Stacking and SystemsDirect Methanol Fuel Cells: Performance, Testing, and DiagnosisDegradation Mechanisms and Mitigation StrategiesApplicationsChallenges and Perspectives of Direct Methanol Fuel CellsMOLTEN CARBONATE FUEL CELLSIntroduction to Molten Carbonate Fuel CellsCurrent Technologic Status of Molten Carbonate Fuel CellsElectrochemical Processes in Molten Carbonate Fuel CellsComponents of Molten Carbonate Fuel CellsStructure and Performance of MCFCsSchematic of MCFC Power Generation SystemsFabrication and Operation of MCFCsMCFC Power PlantMajor Factors Affecting the Performance and Lifetime of MCFCsChallenges and Perspectives of MCFCs

Über den Autor / die Autorin

Dr. Jiujun Zhang is a Senior Research Officer, PEM Catalysis Core Competency Leader and project manager for several fuel cell projects at the Institute for Fuel Cell Innovation, National Research Council of Canada (NRC-IFCI). Dr. Zhang has over 26 years of research and development experience in electrochemical theory and application. Dr. Zhang holds 5 adjunct professorships including one at the University of Waterloo and one at the University of British Columbia and has coauthored 130 research papers published in refereed journals and holds over 10 US patents. Dr. Zhang has also produced over 60 industrial technical reports.

Dr. Hansan Liu is a Research Associate at the NRC Institute for Fuel Cell Innovation, Canada. His research interests consist of fuel cell electrocatalysis for oxygen reduction and methanol oxidation, electrode materials for rechargeable batteries, photoelectrocatalysis, and aerosol techniques for nanomaterial synthesis. Dr. Liu has authored or co-authored over 40 scientific journal papers/industrial technical reports, two book chapters, and one patent.

Zusammenfassung

In this handbook and ready reference, editors and authors from academia and industry share their in-depth knowledge of known and novel materials, devices and technologies with the reader. The result is a comprehensive overview of electrochemical energy and conversion methods, including batteries, fuel cells, supercapacitors, hydrogen generation and storage as well as solar energy conversion. Each chapter addresses electrochemical processes, materials, components, degradation mechanisms, device assembly and manufacturing, while also discussing the challenges and perspectives for each energy storage device in question. In addition, two introductory chapters acquaint readers with the fundamentals of energy storage and conversion, and with the general engineering aspects of electrochemical devices.

With its uniformly structured, self-contained chapters, this is ideal reading for entrants to the field as well as experienced researchers.

Bericht

"In this handbook gives a comprehensive overview of electrochemical energy and conversion methods." (Energy Database, 2012)